DE102010041936A1 - Method and detection system for detecting an electrical line - Google Patents

Abstract

The invention relates to a method for detecting an electrical line (307) having at least two electrical line cores (311, 313, 315), characterized in that an electrical variable is applied to the two electrical line cores (311, 313) to form an electromagnetic field , whereby a field size corresponding to the electromagnetic field is detected. The invention also relates to a detection system.

Description

The invention relates to a method and a detection system for detecting an electrical line. The invention further relates to a loading module and a detector.

State of the art

It is known to detect electrical lines in walls, ceilings or floors by measuring the radiated from the electrical lines electric field. This electric field (E field) forms due to the voltage applied to the electrical lines mains voltage of, for example, 110 V or 230 V with 50 Hz or 60 Hz or 380 V with 50 Hz or 60 Hz for three-phase. The measurement circuits of conventional electric field measuring E-field sensors are designed to detect the 50 Hz and 60 Hz, respectively.

The disadvantage, however, is that the known sensors can not differentiate between E-fields which are radiated from the line to be found, and E-fields which are emitted by interferers, which are numerous to find in domestic use or on construction sites. Such interferers may be, for example, household electrical appliances.

A further disadvantage is that the spreading of the E-field is favored by, for example, damp walls and conductive tiles, which further complicates detection and, in particular, localization.

The publication DE 40 30 634 A1 discloses a method for finding wire conductors. Here, a radio transmitter is connected to a single line wire, the line wire serves as a transmitting antenna of the radio transmitter. A high-frequency carrier frequency is then fed into the line conductor and the propagating E field is measured by means of a radio receiver.

A disadvantage of the known method is in particular that a complex radio transmitter is needed. Furthermore, the high-frequency waves can generate interference fields and affect the functioning of electronic devices.

Disclosure of the invention

The object underlying the invention can therefore be seen to provide a method and a detection system for the detection of an electrical line, which overcome the known disadvantages and enable easy locating the electrical line.

The object is achieved by means of the respective subject matter of the independent claims. Advantageous embodiments are the subject of each dependent subclaims.

The invention includes the idea of specifying a method for detecting an electrical line. The line comprises at least two electrical wires, preferably three electrical wires. For example, a conductor may be a protective conductor, which may also be referred to as a PE conductor, PE standing for "protective earth". For example, a conductor may also be a neutral, which may also be referred to as a PEN conductor, where PEN stands for "protective earth neutral". In particular, a conductor can also be a neutral conductor, which in connection with direct current can also be referred to as a center conductor. A neutral conductor may also be referred to as an N conductor, where N stands for "neutral".

According to the invention, the two conductor wires are subjected to an electrical variable, so that an electromagnetic field is formed around the conductor wires. A field size corresponding to the electromagnetic field is detected accordingly.

In particular, the invention offers the advantage that due to the active loading of the two conductor cores, an adapted electromagnetic field which takes into account the environmental parameters of the conductor can be generated, so that, for example, an influence of a moist wall can be minimized in an advantageous manner.

The invention further includes the idea of specifying a detection system for detecting an electrical line with at least two electrical leads. The detection system, which may also be referred to as a measuring system, comprises a detector for detecting a field size corresponding to an electromagnetic field. Furthermore, according to the invention, an admission module is provided, which is set up to apply an electrical variable to the two electrical line conductors. The detection system is preferably set up to carry out the method according to the invention.

The energizing module is electrically connected to the two electrical wires and energizes the two wires with an electrical size. For example, the loading module may have a load module for generating an electrical load on the two electrical wires. The load module, so to speak, impresses a current on the line to be searched for. Preferably, the stream may be one have a defined course. In particular, the detector, which may also be referred to as a measurement receiver, is moved over a wall covering the conduit and measures the magnetic field (B field) resulting from the current flow. According to another embodiment, the electric field (E-field) can also be measured, in particular if the load module generates high-frequency currents.

For example, in another embodiment, the apply module may include an induction module for inducing an electrical voltage in the two electrical leads. The induction module is connected to the line to be searched and induces a voltage in the line to be searched. Preferably, a voltage with a defined course is induced. In particular, the detector or measuring receiver is moved over the wall covering the line and measures the E field of the induced voltage, in particular the E field of the induced voltage profiles.

Since in both cases-induced voltage and impressed current-a temporal course of the respective applied electrical variable can be varied, corresponding electromagnetic fields characteristic of the applied electrical quantity are formed, which can also be referred to as measuring fields. The detected fields can thus be assigned to the admission module in a simple and unambiguous manner, so that an identification of the applied line is reliably enabled. Furthermore, a distinction can be made between electromagnetic interference fields and the measuring fields in an advantageous manner. Preferably, the electrical quantity is modulated. In particular, an influence of a wall moisture can be minimized by modulating a frequency of the electrical variable. Preferably, the detector comprises a demodulator for demodulating the modulated injected signals.

The detector may preferably comprise a sensor for detecting an electric field and / or a magnetic field. Preferably, the detector comprises a Hall sensor, one or more coils, an AMR sensor based on the anisotropic magnetoresistive (AMR) effect, or a GMR sensor based on the giant magnetoresistance (GMR) effect or giant magnetoresistance. Effect, or one or more electrodes.

According to one embodiment, the loading module is arranged in a housing with two electrical contacts for respectively contacting the two electrical wires. As a result, a particularly simple electrical connection of the admission module is achieved with the line wires. Preferably, the two electrical contacts on clamped connections, so that the loading module can be clamped to the two electrical wires. Preferably, the housing is formed to be plugged into an electrical outlet. The housing has, for example, one or more plug contacts or pins. According to another embodiment, the housing has an adapter, so that the housing can be detachably plugged or fastened in a luminous means holder. Preferably, the adapter comprises a threaded socket, which can be screwed into a threaded socket of a lamp.

According to another embodiment, the admission module has a transmitter, which in particular emits recognition signals. These detection signals can be used in particular for identifying the admission module. The detection signals can also be referred to as identification signals. The detector preferably has a detector receiver which receives the detection signals emitted by the application module. Thus, an unambiguous association between a loading module and a detector can be effected in an advantageous manner. This offers the particular advantage that several admission modules and / or multiple detectors can be used at the same time, as an unambiguous assignment is possible at any time. Preferably, the loading module and the detector communicate by means of Bluetooth and / or W-LAN and / or the ZigBee protocol and / or the irDA (infrared transmission) protocol. The transmitter and the detector receiver are then designed for the corresponding communication protocols.

According to another embodiment, the detector has a detector transmitter, which in particular emits control signals. Preferably, the control signals are received by a receiver of the loading module, so that the detector can advantageously actively control and for example parameterize the loading module. The detector transmitter communicates with the receiver analogously to the communication between the transmitter and the detector receiver, i. H. in particular via Bluetooth, WLAN, ZigBEE and / or irDA.

The invention will be explained below with reference to preferred embodiments with reference to figures. Show here

1 an admission module,

2 a load module,

3 another load module,

4a a side view of a coil,

4b a top view of the coil 4a .

4c to 4i each a different coil arrangement,

5 a block diagram of a load module

6 another admission module,

7 a modulation of the output signal,

8a and 8b they receive measurement signals according to the modulation 7 .

9 another admission module

10a and 10b the admission module 9 at a power outlet,

11 another admission module,

12 a coupling of an induction voltage

13 how the induction voltage is loaded,

14 a classic nullification,

16 an admission module,

17 a modulation of the output signal

18a and 18b the received measurement signals according to the modulation 17 .

19 a housing of a loading module and an adapter and

20 a flow diagram of an embodiment of a method according to the invention.

Hereinafter, like reference numerals designate like features.

1 shows an admission module 101 , The admission module 101 includes a load module 103 for generating an electrical load on the two electrical conductor wires, which may be referred to as a forward conductor and as a return conductor, respectively. Will now be the load module 103 connected to the forward and return conductors, so flows at an applied voltage due to the electrical load generated by means of the load module same electric current in the outgoing and in the return conductor with different signs. It can be provided that a mains voltage is already present. However, it can also be provided that a voltage must first be applied to the forward conductor and to the return conductor. Due to the fact that the same current flows in the forward and return conductor but with different signs, the magnetic fields generated by the forward and return conductors usually cancel each other out. However, only if the return and return conductors are arranged at the same position. This is physically not possible with cables. If the line comprises copper wire, especially if the wires are copper strands, then the magnetic fields would only extinguish if the forward and return conductors were interwoven, which is not according to the regulations of the Association of Electrical Engineering, Electronics and Information Technology (VDE) allowed is. The measuring principle according to the invention advantageously uses this circumstance.

But if, for example, a line is not laid properly or for other reasons, for example, due to the symmetry of the return conductor, the magnetic fields extinguish, so can be performed according to a preferred embodiment, a separation of the forward and return conductors, which 2 is shown.

2 shows a load module 201 , which with a PE conductor 203 , an N conductor 205 and an electrical conductor 207 , which may also be generally referred to as an L-conductor, electrically connected. As can be seen, the respective terminals of the load module 201 with the PE conductor 203 , the N conductor 205 and the L leader 207 in different positions, so that between a forward conductor, L-conductor 207 or N conductor 205 depending on the sign of the voltage, and a return conductor, according to N conductor 205 or L-conductor 207 , no symmetry prevails, so that the B-fields can not wipe out. In this respect, preferably only one line core can be used as a conductor, in which case the forward or return line is carried out separately. Particularly in the case of three-phase lines, the electric current of only one of the three conductors will be modulated in order to advantageously avoid the above described symmetric-related cancellations. It can also be provided according to a further embodiment that alternately in each of the three conductors, a modulated current is generated. As a result, a dimension of the electrical line, which can also be generally referred to as a power cable, can be detected better in an advantageous manner. Preferably, the power cable is a three-phase cable.

3 shows another embodiment of the method according to the invention. One as a load module 301 formed admission module is with two contacts 303a and 303b into a power outlet 305 plugged. The power outlet 305 is with a line to be detected 307 connected, which behind a wall 309 is arranged. The administration 307 includes an L-conductor 311 , an N conductor 313 and a PE conductor 315 , where the contact 303a with the N-conductor 313 and the contact 303b with the L-conductor 311 are connected. Furthermore, the admission module comprises 301 a variable resistor 317 which is between the two contacts 303a and 303b is switched. A controller 319 controls a resistance value of the variable resistor 317 , For example, the controller 319 include a microcontroller.

One in the ladders 311 and 313 flowing electricity is generated by means of a mains supply. The load module 301 generates an electrical load. In particular, an electrical load is modulated by means of the load module. The flowing current is marked with I. As a result, a magnetic field B is formed around the line 307 out. A detector 321 which in this embodiment a coil 323 detects, detects the magnetic field by a coil induced voltage U _{M is} measured.

The magnetic field may preferably also be measured by means of a Hall sensor, an AMR sensor, a GMR sensor or other integrated sensors which may be rotatable in their z-axis. At the coil 323 As a result of the rotation in the z-axis, a surface of the coil changes perpendicularly through the magnetic field. In this way, in particular, a vertex can be determined in which a turning to the left and to the right leads to a decrease in the induced voltage, which can also be referred to as an induction voltage. The y-axis of the coil then points to the line to be found 307 , As a result, at any point in the x-axis, a direction of travel, in particular left or right, can be indicated, where the line to be found 307 is. By appropriate signal processing, in particular intelligent signal processing, can in particular from the modulation of the induction voltage on the current flow in the line 307 getting closed. Since the current profile, which can be, for example, pulse width modulated and / or frequency modulated and / or may have a digital signature, signal processing is known, can be detected on the modulation. If the induced voltage is measured, the course of the B-field can be determined by calculation and thus on that in the line 307 flowing electricity. As a result, an unambiguousness of the detection of the line is advantageously 307 guaranteed.

4a shows a side view of an embodiment of a coil 401 , which can be used in a detector according to the invention. The sink 401 has an initial contact 403a and a final contact 403b on which an induction voltage in the coil 401 can be measured. 4b shows a plan view of the coil 401 out 4a ,

4c to 4i each schematically show a detector housing 405 comprising coil assemblies comprising one or more coils 401 out 4a and 4b , for the sake of clarity, the initial contact 403a and the end contact 403b not shown. In connection with the various coil arrangements and the corresponding magnetic field measuring method is described in detail. The sink 401 can also be referred to as a sensor.

In 4c has the detector housing 405 a coil 401 which is stationary in the detector housing 405 is arranged. Ie. in particular, that the coil 401 can not turn around a space axis. The sink 401 or sensor can measure the B field only in one place. By means of spatial displacement or method, the maximum B-field over the line 307 being found.

In 4d has the detector housing 405 a coil 401 which is rotatably mounted about its z-axis. This can detect whether the magnetic field is left or right relative to the line 307 is larger. In particular, a direction can be displayed in which the line 307 located.

Both detector housings 405 in 4c and 4d now each have a coil 401 on. The spools 401 can also be referred to as a single sensor in this case.

In 4e has the detector housing 405 three parallel to each other arranged coils 401 on, which are each arranged stationary. With this coil arrangement can be detected in particular advantageously, whether the magnetic field right or left relative to the line 307 is larger or smaller. In particular, a direction can be displayed in which the line 307 located.

In 4f has the detector housing 405 three coils or sensors 401 on. Two of the three coils 401 have a different orientation in their z-axis than the third coil. That is, the two coils are twisted about their z-axis with respect to the third coil. As a result, a receiving lobe is changed in an advantageous manner. Preferably, the three coils 405 arranged in parallel with their respective z-axis, wherein a rotation about the z-axis is different. Preferably, the two are outer coils twisted relative to the middle coil. With this coil arrangement can be detected in particular advantageously, whether the magnetic field right or left relative to the line 307 is larger or smaller. In particular, a direction can be displayed in which the line 307 located.

In 4g has the detector housing 405 four coils 401 on. Two each of the four coils 401 are arranged opposite each other in parallel. Thus, it can be particularly advantageously detected whether the detector housing 405 parallel or not to the line 307 is relocated.

In 4h has the detector housing 405 five coils 401 on. Four coils 401 are analogous to those in 4g arranged coil assembly, wherein the fifth coil 401 is arranged centrally between the oppositely arranged parallel coil pairs. By means of this coil arrangement can be detected in particular advantageously, whether the B-field left or right relative to the line 307 bigger or smaller and whether the detector housing 405 parallel or not to the line 307 is relocated.

4i shows the same coil arrangement as the 4h , unlike the 4h the central coil 401 is rotatably mounted in the x-axis and y-axis, in particular rotatable in the xy plane. This can be detected in an advantageous manner, whether the B-field left or right relative to the line 307 bigger or smaller is whether the detector housing 405 directly above the line 307 located and whether the detector housing 405 parallel or not to the line 307 is relocated.

5 shows a block diagram of an admission module 501 comprising a load module 503 , which is designed as a controllable variable electrical resistance. The admission module 501 is electric with an L-conductor 505 and an N conductor 507 connected so that the load module 503 generates an electrical load in the circuit thus formed. The L-conductor 505 , the N-leader 507 and a PE conductor 509 are electrical leads of an electrical line (not shown). The load module 503 is with a driver 511 connected, which in turn with a microcontroller 513 connected is. The microcontroller 513 can about the driver 511 the load module 503 control, in particular set a resistance value. Preferably, the resistance value can be modulated. Furthermore, three switches S1, S2 and S3 are provided, via which the load module 503 an identifier, such as a number, can be assigned. The three switches S2, S2 and S3 are preferably adjustable from an outside of a load module housing (not shown) and in particular accessible. Preferably, the modulation is dependent on the assigned identifier, so that a detector the measured signals uniquely the admission module 501 can assign. Thus, a parallel operation of several load modules is in particular advantageously possible.

The admission module 501 also has a WLAN module 515 and a bluetooth module 517 in particular each comprising a corresponding transmitter and receiver. By means of the WLAN module 515 and the Bluetooth module 517 In particular, a further communication with the measuring receiver or detector is possible, which has a corresponding WLAN module and a corresponding Bluetooth module.

6 shows an admission module 601 comprising a load module formed as a variable resistor 603 which is analogous to 5 with a driver 605 which is connected by means of a microcontroller 607 is controlled. The load module 603 is with two electrical wires 609a and 609b connected and generated due to the existing mains voltage an electrical load, so that in the line wires 609a and 609b an electric current I flows. In a measuring receiver or detector 611 which is a coil 613 includes, one in the coil 613 induced voltage U _M measured.

7 shows an embodiment of a modulation of the current and a synchronization of the measuring receiver 611 and the admission module 601 , A driver voltage U is plotted over the time t. Since a drive voltage U a resistance value of the load module 603 corresponds, so one in the wires 609a and 609b be set flowing current value, which in turn generates a corresponding magnetic field. The transmission starts with a start block 701 which in particular the detector 611 signaled the beginning of a measurement. This is followed by an identification block 703 , which may also be referred to as a "Device Name" block. The identifier block 703 transmits a unique load module identifier so that the test receiver 611 the detected signals clearly the load module 603 can assign. After the identification block 703 Different frequencies f1, f2, f3, f4 and f5 are modulated at respective time intervals t1, t2, t3, t4 and t5. Preferably, more than 5 or less than 5 frequency blocks are used for modulation.

8a and 8b show the signals on the measuring receiver side, where 8a Measuring signals with a higher intensity, for example 70% of a measuring receiver display, shows as 8b which signals with a lower intensity, for example 30% of a measuring receiver display. Plotted in the respective left graph is the induced voltage U _M over time t. The respective right graph shows the Fourier transform measured spectrum from the left graph. Plotted is insofar a voltage U over a frequency f. The block 801 denotes the detected signals corresponding to the identification block 703 , U1, U2, U3, U4 and U5 denote the detected signals corresponding to the modulated frequencies f1 to f5. In the right graph so the transmitted spectrum is visible and can be used for example in a level meter.

Once the digital startup block 701 and the identifier block 703 be detected, an evaluation of the frequencies is possible and thus an indication of the receiver level. For a calibration, explicit and defined pause times of the load modulation can preferably be introduced, for example between the frequency blocks f1 to f5. During the test receiver 611 known breaks are from the load module 603 no currents on the wires 609a and 609b impressed. The measuring signal, what during these pauses from the measuring receiver 611 , which can also be generally referred to as a measuring module, can thus be used in particular as a background signal, whereby external, interfering magnetic fields can be masked out in an advantageous manner. Thus, in particular, an accuracy of the measuring module 611 increase. Preferably, the calibration is performed once or continuously or at specific time intervals.

9 shows an admission module 901 comprising an induction module 903 for inducing an electrical voltage in two electrical wires (not shown).

The admission module 901 can, how 10a and 10b show to a socket (not shown) of a room 1001a and is connected to an existing power line through this outlet. The space 1001a is by means of a fuse 1003a to a 400 V home distribution network 1005 connected. Further backups 1007 are between the home distribution network 1005 and a 20 kV supply 1009 connected. In a substation 1011 will be the 20 kV of the feed 1009 to 400 V for the home distribution network 1005 downshifted. The fuses 1007 are each in front of the substation 1011 connected. Further show 10a and 10b two more rooms 1001b and 1001c , which by means of separate fuses 1003b and 1003c to the home distribution network 1005 are switched.

The admission module 901 can detect whether a mains voltage, in particular an AC voltage is applied to the socket. By means of the induction module 903 A defined voltage is applied to ground via the socket in the circuit of the room 1001a induced. If the fuses 1003a . 1003b and 1003c , which can be generally referred to as a space backup, are closed (see. 10a ), this induced voltage is in the neighboring circuits of the rooms 1001b and 1001c also detectable, since there is a galvanic coupling between these spaces. If, however, the fuse 1003a is open, so the induced voltage is only in the room 1001a detectable (cf. 10b ).

11 shows a block diagram of an induction module 1101 trained admission module. The induction module 1101 is with an L-conductor 1103 and an N conductor 1105 an electrical line 1107 connected, the line 1107 another PE conductor 1109 having. The induction module 1101 is with this PE conductor 1109 for earthing by means of a high-resistance base point 1102 also connected. Due to the induced voltage forms around the electrical line 1101 an electric field, what a test receiver 1111 or detector can be detected. The measuring receiver 1111 includes an electrode 1113 , which is preferably formed as a surface electrode. The electrode 1113 is rotatably mounted in its z-axis. One on the electrode 1113 due to the electric field voltage applied by means of a driver or amplifier 1115 strengthened. The detected amplified electrical voltage can then by means of a display device 1117 be read by a user.

The detector 1111 includes at least one electrode 1113 but may comprise a plurality of electrodes which are rotatably mounted in their z-axis. However, other integrated solutions may be provided which may be rotatable in their z-axis. At the electrode or electrodes 1113 As a result of the rotation in the z-axis, the area of the electrode changes 1113 which is perpendicular to the E-field. As a result, it is possible in particular to determine a vertex in which a rotation to the left or right leads to a decrease in the voltage at the electrode 1113 leads. The y-axis of the electrode 1113 then points to the line to be found 1107 , As a result, in particular at any point in the x-axis, a direction of travel (left or right) can be indicated, where the line to be found 1107 is arranged. The induced voltage is a signal processing in the detector 1111 known, so that it can be detected. The induced voltage curve is preferably modulated, preferably pulse-width-modulated, phase-modulated, frequency-modulated or in particular can have a digital signature.

According to a further embodiment, the induced voltage via a transformer 1201 be coupled, like 12 shows closer. The induction voltage U2 can by means of a battery 1203 be generated with a voltage U1. Preferably, however, the induction voltage can also be generated by means of the mains supply voltage. The induction voltage U2 is charged in particular only with the line capacitances and has approximately the no-load voltage U1 of the transformer 1201 , According to another embodiment it can be provided that the induction voltage is coupled in directly directly without a transformer.

13 shows in particular how the induction voltage is loaded. As already in 12 shown, the induction voltage U2 is fed to the ground reference potential. All loads in the network are between the L-conductor 1103 and the N conductor 1105 connected. Therefore, there is no load current over the network loads for U2. Conversely, this means in particular that there is no current from the mains voltage via a secondary winding of the transformer 1201 comes, in particular also several transformers can be provided. Typical loads are denoted by the reference numerals 1301a . 1301b and 1301c characterized. These loads 1301a to 1301c For example, in a metallic housing 1303 be arranged, which by means of the PE conductor 1109 is grounded. The N conductor 1105 and the L-leader 1103 For example, they may be laid in a twisted manner in a wall (not shown). Then it can happen, for example, that thereby one of the ladder 1105 and 1103 completely behind the PE conductor 1109 is hidden. The electrical effect is that this shields the E-field. To prevent this, is by means of a relay 1305 between the L-conductor 1103 and the N conductor 1105 switched, in particular switched cyclically, so that alternately the voltage U2 on the L-conductor 1103 and on the N-ladder 1105 is switched.

14 shows a special case of classic zeroing. In classic zeroing, there is no PE conductor. Here is the neutral conductor 1105 connected to the protective contact of the socket. In one embodiment, the induction module detects 1101 that U2 through the network loads 1301a to 1301c is charged. In particular, an optical and / or acoustic warning signal can then be output. According to a further embodiment, the induction module 1101 measure whether it is a classic nullification. In particular, in this case, the resistance between protective contacts and the L-conductor 1103 and / or the N-conductor 1105 be measured. Preferably, a primary winding current is measured. If it is determined that it is a classic nulling, for example by means of the induction module 1101 , the supply line to the protective contact separated and then it can, for example, a connection via a socket 1403 , in particular a BNC socket, to a ground potential, for example to a heater 1401 be placed. Switching the protective contact to the socket 1403 can in particular by means of another relay 1405 be performed.

15 shows a block diagram of the induction module 1101 out 14 , Here Re2 denotes the further relay 1405 and Re1 the relay 1305 , AD1 denotes a detector circuit which can detect whether a mains voltage exists between the L-wire 1103 and the N conductor 1105 is applied. AD2 indicates a measuring circuit which can measure a coil current. There is also a microcontroller 1501 provided, which receives provided by the circuits AD1 and AD2 detected measurement signals available. Ie. in particular, that the microcontroller 1501 Receives information about the concern of a net voltage and / or the presence of a coil current. Furthermore, it is a driver 1503 provided, which can provide a fed voltage waveform.

The transformer 1203 induces a voltage depending on the voltage curve of the driver 1503 , The microcontroller 1501 supplies the voltage to the driver 1503 , Via switches S1, S2 and S3, in particular the induction module can be assigned an identifier or identity, for example a number. The relevant explanations in connection with the load module also apply analogously to the induction module. As a result, a parallel operation of several load modules is advantageously possible. Via a Bluetooth module 1505 and a WLAN module 1507 The induction module can communicate with a measuring receiver. The relevant versions in connection with the load module apply analogously.

AD1 detects in particular whether a mains voltage is between L and N. In particular, AD2 measures the coil current when Re2 is switched and if it is a classic null. If it is a classic zeroing, the winding current or coil current increases significantly and it can be detected insofar as it is a classic nulling.

16 shows an admission module 1601 comprising an induction module 1603 , which is connected to three leads, PE conductors 1605 , N-conductor 1607 , L-conductor 1609 , connected. In the induction module 1603 For example, it may be the induction module 1101 act. 16 further shows a measuring receiver 1611 or detector for detecting an E-field. It may preferably be at the detector 1611 around the detector 1111 act. The induction module 1603 induces an electrical voltage in the N-conductor 1607 and the L-leader 1609 , so that an electric field around the wires 1605 . 1607 and 1609 formed. The detector 1611 detects this E-field by measuring a voltage U _ind induced in one or more coils.

17 shows an embodiment of a modulation of the voltage and a synchronization of the measuring receiver 1611 and the admission module 1601 , Placed is one in the wires 1607 and 1609 induced voltage U over time t. The transmission starts with a start block 1701 which in particular the detector 1611 signaled the beginning of a measurement. This is followed by an identification block 1703 , which may also be referred to as a "Device Name" block. The identifier block 1703 transmits a unique induction module identifier, so that the measurement receiver 1611 the detected signals clearly the induction module 1603 can assign. After the identification block 1703 Different frequencies f1, f2, f3, f4 and f5 are modulated at respective time intervals t1, t2, t3, t4 and t5. Preferably, more than 5 or less than 5 frequency blocks are used for modulation.

18a and 18b show the signals on the measuring receiver side, where 18a Measuring signals with a higher intensity, for example 70% of a measuring receiver display, shows as 8b which signals with a lower intensity, for example 30% of a measuring receiver display. Plotted in the respective left graph is the induced voltage U _ind over time t. The respective right graph shows the Fourier transform measured spectrum from the left graph. Plotted is insofar a voltage U over a frequency f. The block 801 denotes the detected signals corresponding to the identification block 703 , U1, U2, U3, U4 and U5 denote the detected signals corresponding to the modulated frequencies f1 to f5. In the right graph so the transmitted spectrum is visible and can be used for example in a level meter.

Once the digital startup block 1701 and the identifier block 1703 be detected, an evaluation of the frequencies is possible and thus an indication of the receiver level. For a calibration, explicit and defined pause times of the voltage modulation can preferably be introduced, for example between the frequency blocks f1 to f5. During the test receiver 1611 known breaks are from the load module 1603 no voltages to the wires 1605 and 1609 created. The measuring signal, what during these pauses from the measuring receiver 1611 , which can also be generally referred to as a measuring module, can thus be used in particular as a background signal, whereby advantageously external, interfering E-fields can be masked out. Thus, in particular, an accuracy of the measuring module 1611 increase. Preferably, the calibration is performed once or continuously or at specific time intervals.

In general, the modulation describes the voltage curve in the case of an induction module or the current profile in the case of a load module and the type of information acquisition in the measuring receiver or detector. The voltage curve is generated by means of the induction module. The energy for this purpose is provided in particular by means of a battery or recovered from the battery. The current profile is generated by means of the mains supply or the mains voltage by means of the load module.

The modulation may according to one embodiment be an amplitude, a pulse width and / or a phase modulation.

According to another embodiment, the modulation may be performed with multiple frequencies that change sequentially or multiple frequencies that are generated at the same time.

According to a further embodiment, the modulation may also have a digital signature, so that it can be detected when using multiple load modules and / or multiple induction modules, which line (or which load module or induction module) is detected. This makes it possible in particular advantageously to distinguish adjacent lines.

According to another embodiment, defined pulses with defined pulse widths can additionally be generated within the digital signature, in order in particular to generate conclusions about a detection level. As a result, a low-pass and / or a high-pass behavior of a wall can be taken into account in an advantageous manner. In particular, due to the use of different frequencies, a transfer function is measurable because different frequencies experience different attenuations through the wall. It is therefore advantageously sufficient that the measuring receiver does not measure the frequency, but only a temporal distance to the data block "Device Name" 703 and 1703 , The measuring receiver then has in particular rectifier, which are designed for the corresponding frequency.

According to a further embodiment, the modulation of a digital signature can also be realized over fixed frequencies with different burst pauses.

In another embodiment, a waveform of the modulation may be, for example, a sine, a rectangle, or a triangle. Other signal forms known to the person skilled in the art can also be used.

In general, a synchronization in a communication between the measuring receiver and a loading module comprising a load module and / or an induction module can take place according to one or more of the following possibilities.

For example, no synchronization / communication can take place. The modulation of the load module or the induction module is stored or stored as a constant variable in the measuring module or detector.

For example, a communication / synchronization can take place via the modulated load or via the modulated voltage. In particular, the information is transmitted unidirectionally from the admission module to the measurement module via the load modulation or voltage modulation.

Preferably, a separate unidirectional communication, for example via WLAN, Bluetooth and / or ZigBee. The information is thus transmitted from the admission module to the measurement module via a separate communication path.

Preferably, a separate bidirectional communication takes place, for example via WLAN, Bluetooth and / or ZigBee. The information is therefore transmitted bidirectionally between the load module or the induction module and the measuring module. In this embodiment, the measuring module in particular has the option of actively controlling and / or parameterizing the load module and the induction module.

19 shows an admission module housing 1901 with two plug contacts 1903A and 1903b , which in appropriate shots 1905a and 1905b a power outlet 1907 can be plugged. 19 further shows an adapter 1909 , which is analogous to the socket 1907 also two plug receptacles 1911a and 1911b in which the contacts 1903A and 1903b can be plugged. At one of the shots 1911a and 1911b opposite end is a screw thread 1913 provided, which is designed as a bulb holder. The screw thread 1913 may also be referred to as a light bulb socket. The light bulb socket 1913 can then be screwed into appropriate recordings of lamps. A screw thread as an adapter thread is merely to be regarded as a possible embodiment of an adapter. It is also possible that instead of a screw thread 1913 a clamping plug (not shown) is provided, by means of which the adapter 1909 can be plugged into a fluorescent tube socket or a halogen lamp socket. The adapter may also preferably comprise a clamping connection by means of which the adapter can be connected directly to cable cores.

20 shows a flowchart of an embodiment of a method for detecting an electrical line comprising at least two electrical wires. In a first step 2001 an electrical quantity is applied to the two electrical leads, so that an electromagnetic field forms around the two conductor leads. In a second step 2003 a field size corresponding to the electromagnetic field is detected.

In summary, a measuring system or detection system comprising an admission module with an induction module and / or a load module, wherein in particular also several load modules and / or a plurality of induction modules can be provided, and a measurement receiver, wherein preferably also a plurality of measurement receivers or detectors can be provided, and a corresponding method for detecting an electrical line specified. The induction module is in this case connected in particular to the line to be searched for and induces a voltage with a defined course in it. The measurement receiver, which is moved over the wall, measures the E field of the induced voltage waveforms. Analogously, the load module impresses a current with a defined course. The measuring receiver, which is moved over the wall, measures the magnetic field resulting from the current flow. In particular, the E-field can also be measured, preferably when the load module generates currents that are high-frequency. Due to the variable parameters of the Beaufschlagungsmoduls it is advantageously possible to minimize the influence of, for example, a wall moisture by appropriate frequency selection. In particular, the invention further offers the advantage that it can generally be used in locating devices which have the task of detecting electrical lines.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• DE 4030634 A1 [0005]

Claims (13)

Method for detecting an electrical line ( 307 ) comprising at least two electrical wires ( 311 . 313 . 315 ), characterized in that an electrical quantity on the two electrical wires ( 311 . 313 ) is applied to form an electromagnetic field, wherein a field size corresponding to the electromagnetic field is detected. The method of claim 1, wherein the electrical quantity is modulated. The method of claim 1 or 2, wherein the electrical quantity is an electrical current and / or an electrical voltage. Method according to one of the preceding claims, wherein the field size is an electrical and / or magnetic flux density. Detection system ( 301 ; 321 ) for detecting an electrical line having at least two electrical wires ( 311 . 313 . 315 ), with: - a detector ( 321 ) for detecting a field size corresponding to an electromagnetic field, - characterized in that a loading module ( 301 ), which is set up, an electrical variable on the two electrical wires ( 311 . 313 ). Detection system ( 301 ; 321 ) according to claim 5, wherein the loading module ( 301 ) is further configured to modulate the electrical quantity and the detector comprises a demodulator for demodulating a modulated electric and / or magnetic field magnitude signal. Detection system ( 301 ; 321 ) according to claim 5 or 6, wherein the loading module ( 301 ) a load module ( 103 ) for generating an electrical load on the two electrical wires ( 311 . 313 ) and / or an induction module ( 903 ) for inducing an electrical voltage in the two electrical wires ( 311 . 313 ) having. Detection system ( 301 ; 321 ) according to one of claims 5 to 7, wherein the loading module ( 301 ) in a housing ( 1901 ) with two electrical contacts ( 1903A . 1903b ) for respectively contacting the two electrical wires ( 311 . 313 ) is arranged. Detection system ( 301 ; 321 ) according to claim 8, wherein the housing ( 1901 ) an adapter ( 1909 ) for releasably securing the housing ( 1901 ) in a bulb socket. Detection system ( 301 ; 321 ) according to one of claims 5 to 9, wherein the loading module ( 301 ) a transmitter ( 517 ) for transmitting detection signals and the detector ( 321 ) comprise a detector receiver for receiving the emitted detection signals. Detection system ( 301 ; 321 ) according to any one of claims 5 to 10, wherein the detector ( 321 ) comprise a detector transmitter for transmitting control signals and the biasing module comprises a receiver for receiving the transmitted control signals. Admission module ( 301 ) according to one of claims 5 to 11. Detector ( 321 ) according to one of claims 5 to 11.

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